Researchers set new record for brightness of quantum dots
James E. Kloeppel, U of I News Bureau
- Professor Cunning has demonstrated enhanced brightness of quantum dots.
- A quantum dot is a tiny piece of semiconductor material that will fluoresce with visible light when illuminated with invisible ultraviolet light.
- Possible uses for the enhanced brightness include detecting DNA, cancer cells, spores, and viruses.
By placing quantum dots on a specially designed photonic crystal, ECE Illinois researchers have demonstrated enhanced fluorescence intensity by a factor of up to 108. Potential applications include high-brightness light-emitting diodes, optical switches, and personalized, high-sensitivity biosensors.
“We are using photonic crystals in a new way,” said Brian T Cunningham, ECE professor and corresponding author of a paper published in the August issue of the journal Nature Nanotechnology. “We tune them to the specific wavelength of a laser used to stimulate the quantum dots, which couples the energy more efficiently and increases the brightness.”
A quantum dot is a tiny piece of semiconductor material 2 to 10 nanometers in diameter (a nanometer is 1 billionth of a meter). When illuminated with invisible ultraviolet light, a quantum dot will fluoresce with visible light.
To enhance the fluorescence, Cunningham and his colleagues begin by creating plastic sheets of photonic crystal using a technique called replica molding. Then they fasten commercially available quantum dots to the surface of the plastic.
“We designed the photonic crystal to efficiently capture the light from an ultraviolet laser and to concentrate its intensity right within the surface where the quantum dots are located,” said Cunningham, who also is affiliated with the University’s Beckman Institute, Micro and Nanotechnology Laboratory, and Institute for Genomic Biology. “Enhanced absorption by the quantum dots is the first improvement we made.”
Enhanced, directed emission from the quantum dots is the second improvement.
Quantum dots normally give off light in all directions. However, because the researchers’ quantum dots are sitting on a photonic crystal, the energy can be channeled in a preferred direction – toward a detector, for example.
While the researchers report an enhancement of fluorescence intensity by a factor of up to 108 compared with quantum dots on an unpatterned surface, more recent (unpublished) work has exceeded a factor of 550.
“The enhanced brightness makes it feasible to use photonic crystals and quantum dots in biosensing applications from detecting DNA and other biomolecules, to detecting cancer cells, spores and viruses,” Cunningham said. “More exotic applications, such as personalized medicine based on an individual’s genetic profile, may also be possible.”
Funding was provided by the National Science Foundation and SRU Biosystems. Part of the work was carried out in the University’s Center for Microanalysis of Materials, which is partially supported by the U.S. Department of Energy.